Armature having a core leg position fixing member for reducing thermal stress

ABSTRACT

This armature has a core leg portion fixing member that is provided in a slot so as to overlap with a part at a position different from a position in an axial direction corresponding to a joint portion, and that includes a first fixing layer for fixing an armature core and a leg portion.

TECHNICAL FIELD

The present disclosure relates to an armature.

BACKGROUND ART

Conventionally, an armature including an armature core provided with a plurality of slots extending in a central axis direction is known. Such an armature is disclosed in Japanese Unexamined Patent Application Publication No. 2006-141076 (J P 2006-141076 A) and Japanese Unexamined Patent Application Publication No. 2011-244596 (JP 2011-244596), for example.

JP 2006-141076 A discloses a rotary electric machine stator (hereinafter, referred to as a “stator”) having a stator core provided with a plurality of slots extending in a central axis direction (axial direction). A coil is disposed in the slots of the stator. The coil is divided into three in the axial direction. Specifically, the coil is configured of one linear portion conductor segment that has a linear shape and two coil end portion conductor segments that have a substantially U-shape.

Further, in J P 2006-141076 A, an insulating insulator is disposed in each of the slots. The insulating insulator is formed of resin (formed by molding resin). Further, the insulating insulator is provided with an insertion hole into which the linear portion conductor segment is inserted. The insertion hole is set to such a size that the linear portion conductor segment is press-fitted, and the linear portion conductor segment is press-fitted into the insulating insulator disposed in the slot. The linear portion conductor segment is fixed to the stator core by an insulating insulator and is configured to ensure the insulation performance of the linear portion conductor segment and the stator core. The linear portion conductor segment and the coil end portion conductor segment are joined inside the insertion hole of the insulating insulator and thus, the coil is configured.

JP 2011-244596 A discloses a stator including a stator core that is provided with a plurality of slots extending in a central axis direction (axial direction). A coil is disposed in the slots of the stator. The slots of the stator are each provided with a foamed resin sheet sandwiched between an inner wall surface of the slot and the coil. By heating and expanding the foamed resin sheet while the foamed resin is sandwiched between the inner wall surface of the slot and the coil, a foamed resin portion is formed between the inner wall surface of the slot and the coil. The coil is fixed to the inner wall surface of the slot by curing (thermosetting) the foamed resin portion.

RELATED ART DOCUMENTS Patent Documents

Patent Document 1: Japanese Unexamined Patent Application Publication No. 2006-141076 (JP 2006-141076 A)

Patent Document 2: Japanese Unexamined Patent Application Publication No. 2011-244596 (JP 2011-244596 A)

SUMMARY Problem to be Solved

However, since the stator described JP 2006-141076 A is provided with an insulating insulator formed of resin (formed by molding resin), equipment for performing resin molding including a resin molding mold is required. Thus, in the stator described in JP 2006-141076 A, there is an inconvenience that the configuration of equipment (devices) for manufacturing the stator becomes complicated.

Here, a coefficient of thermal expansion of the stator core and the coefficient of thermal expansion of the coil may be different values. In this case, when the temperature of the stator core and the coil changes, the expansion length (contraction length) of the stator core and the expansion length (contraction length) of the coil differ due to the difference in the coefficient of thermal expansion. Thus, in the stator described in JP 2011-244596 A, stress (thermal stress) is generated in the stator core and the coil via a fixing agent. It is considered that when thermal stress is applied to a joint part between a linear portion conductor segment and a coil end conductor segment, a mechanical strength of the joint part may decrease due to the thermal stress.

As described above, in the stators described in JP 2006-1410676 A and J P 2011-244596 A, there is a problem that it is difficult to reduce the thermal stress on the joint part of the linear portion conductor segment and the coil end portion conductor segment (a joint portion of a plurality of segment conductors) while preventing the manufacturing equipment of the stator (armature) from becoming complicated.

The present disclosure has been made to solve the above problems, and one object of the present disclosure is to provide an armature in which thermal stress on a joint portion of a plurality of segment conductors can be reduced while preventing armature manufacturing equipment from becoming complicated.

Means for Solving the Problem

In order to achieve the above object, the armature in one aspect of the present disclosure includes an armature core provided with a plurality of slots extending in a central axis direction; a coil portion in which leg portions of a plurality of segment conductors disposed so as to face each other in the central axis direction are joined in one slot of the slots or in a joint portion on an outer side of the slot in the central axis direction; and a core leg portion that is provided in the slot, in a part at a position different from the position in the central axis direction corresponding to the joint portion and that includes a first fixing layer that fixes the armature core and the leg portion.

In the armature according to one aspect of the present disclosure, as described above, the configuration is such that the first fixing layer of the core leg portion fixing member is provided in the part at the position different from the position in the central axis direction corresponding to the joint portion so as to fix the armature core and the leg portion. As a result, in the central axis direction, since the first fixing layer is not provided in the joint portion, the relative position between the joint portion and the armature core is not fixed by the first fixing layer. Thus, even if the expansion length (contraction length) along the central axis direction of the armature core and the expansion length (contraction length) along the center axis direction of the leg portion are different sizes due to the armature core and the leg portion being heated or cooled, the thermal stress can be relieved, since the relative positions of the joint portion and the armature core in the central axis direction can be changed. Further, in the present disclosure, since the first fixing layer of the core leg portion fixing member is configured to fix the armature core and the leg portion, there is no need to form the core leg portion fixing member by molding resin so that the segment conductor can be press-fitted to the core leg portion fixing member. In this way, it is possible to prevent the armature manufacturing equipment from becoming complicated since it is not necessary to mold the resin. As a result, it is possible to reduce the thermal stress on the joint portions of the plurality of segment conductors while preventing the armature manufacturing equipment from becoming complicated. The term “joint portion” has a broad meaning including not only a portion joined with a bonding agent but also a portion that is only in contact without a bonding agent.

According to the present disclosure, as described above, it is possible to reduce the thermal stress on the joint portion of the plurality of segment conductors while preventing the armature manufacturing equipment from becoming complicated.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a plan view showing a configuration of a stator (rotary electric machine) according to a first embodiment.

FIG. 2 is a perspective view showing the configuration of the stator according to the first embodiment.

FIG. 3 is an exploded perspective view of the stator according to the first embodiment.

FIG. 4 is a plan view showing a configuration of a stator core according to the first and second embodiments.

FIG. 5 is a sectional view showing a configuration of a first insulating member and a second insulating member according to the first embodiment.

FIG. 6 is a circuit diagram showing a wiring configuration of a coil portion according to the first embodiment.

FIG. 7 is a perspective view showing a part of a second coil assembly according to the first embodiment.

FIG. 8 is a cross-sectional view showing a configuration of a segment conductor according to the first embodiment.

FIG. 9 is a figure showing a configuration of a first segment conductor according to the first embodiment.

FIG. 10 is a figure showing a configuration of a second conductor according to the first embodiment.

FIG. 11 is a diagram showing a configuration of a power segment conductor according to the first embodiment.

FIG. 12 is a figure showing a configuration of an outer radial side neutral point conductor according to the first embodiment.

FIG. 13 is a figure showing a configuration of an inner radial side neutral point conductor according to the first embodiment

FIG. 14 is a sectional view taken along line 1000-1000 in FIG. 1.

FIG. 15 is a figure showing the relationship between a disposition position of a first insulating member and a disposition position of a second insulating member according to the first embodiment.

FIG. 16 is a sectional drawing schematically showing a configuration of the first insulating member according to the first embodiment.

FIG. 17 is a sectional drawing showing the configuration of the first insulating member and the second insulating member including a fixing layer before foaming according to the first embodiment.

FIG. 18 is sectional drawing showing a boundary vicinity of the first insulating member and the second insulating member including the fixing layer after foaming according to the first embodiment.

FIG. 19 is a sectional view showing the configuration of the second insulating member according to the first embodiment

FIG. 20 is a perspective view showing the configuration of the second insulating member according to the first embodiment.

FIG. 21 is a figure showing the thickness of the first insulating member and the thickness of the second insulating member according to the first embodiment.

FIG. 22 is a perspective view showing the configuration of a stator according to a second embodiment.

FIG. 23 is an exploded perspective view of the stator according to the second embodiment.

FIG. 24 is a cross-sectional view showing a configuration of a segment conductor according to the second embodiment. (FIG. 24A is a cross-sectional view of a leg portion. FIG. 24B is a cross-sectional view of a coil end portion.)

FIG. 25 is a perspective view showing a configuration of a first conductor according to the second embodiment. (FIG. 25A is a perspective view of the first conductor viewed from the outside in outer radial direction. FIG. 25B is a perspective view of the first conductor viewed from the inner radial side.)

FIG. 26 is a perspective view showing a configuration of a second conductor according to the second embodiment. (FIG. 26A is a perspective view of the second conductor viewed from the outer radial side. FIG. 26B is a perspective view of the second conductor viewed from the inner radial side.)

FIG. 27 is a cross-sectional view along the radial direction of the inside of a slot according to the second embodiment.

FIG. 28 is a partially enlarged view of a vicinity of a contact portion in FIG. 27.

FIG. 29 is a sectional drawing showing a configuration of an insulating member according to the second embodiment.

FIG. 30 is a sectional drawing showing a configuration of an insulating layer and a fixing layer of the contact portion insulating part according to the second embodiment.

FIG. 31 is a sectional drawing showing a configuration of an insulating layer and a fixing layer of a core leg portion insulating part according to the second embodiment.

FIG. 32 is a flowchart showing a manufacturing method of the stator according to the second embodiment.

FIG. 33 is a plan view showing a configuration of the stator according a first modification of the first and second embodiments.

FIG. 34 is a diagram showing a configuration of a stator according a second modification of the first and second embodiments.

DESCRIPTION

Hereinafter, an embodiment of the present disclosure will be described with reference to the drawings.

First Embodiment

[Structure of Stator]

The structure of a stator 100 according to the first embodiment will be described with reference to FIGS. 1 to 21. The stator 100 has an annular shape centered around a central axis C1. The stator 100 is an example of an ‘armature_ in the claims.

In the specification of the application, an ‘axial direction (central axis direction, axis direction)_means a direction (Z direction) along the central axis C1 of the stator 100 (a rotational axis of a rotor 101) as shown in FIG. 1. A ‘circumferential direction_ means a circumferential direction (A1 direction, A2 direction) of the stator 100. A ‘radial direction_ means a radial direction (R direction) of the stator 100. An ‘inner radial side_ means a direction (R1 direction) toward the central axis C1 of the stator 100 along the radial direction. Further, an ‘outer radial side_ means a direction (R2 direction) toward the outside of the stator 100 along the radial direction.

The stator 100 configures a part of a rotary electric machine 102 together with the rotor 101. The rotary electric machine 102 is configured as a motor, a generator, or a motor/generator, for example. As shown in FIG. 1, the stator 100 is disposed on the outer radial side the rotor 101 in which a permanent magnet (not shown) is provided. That is, in the first embodiment, the stator 100 configures a part of the inner rotor type rotary electric machine 102.

As shown in FIG. 2, the stator 100 includes a stator core 10, a first insulating member 20, and a coil portion 30. Further, as shown in FIG. 3, the coil portion 30 includes a first coil assembly 30 a (non-lead side coil) and a second coil assembly 30 b (lead side coil). Further, as shown in FIG. 3, the coil portion 30 is composed of a plurality of segment conductors 40. In addition, in the first embodiment, the stator 100 includes a second insulating member 21 that is provided separately from the first insulating member 20. The stator core 10 is an example of an ‘armature core_ in the claims. The first insulating member 20 is an example of a “core leg portion fixing member” in the claims. The second insulating member 21 is an example of a “first joint portion insulating member” in the claims.

(Structure of Stator Core)

The stator core 10 has a cylindrical shape with the central axis C1 (see FIG. 1) as the central axis. Further, the stator core 10 is formed, for example, by stacking a plurality of electromagnetic steel plates (for example, silicon steel plates) in the axial direction. H ere, in the first embodiment, the stator core 10 is formed by stacking a plurality of silicon steel plates having a thermal expansion coefficient K1. As shown in FIG. 4, the stator core 10 is provided with a back yoke 11 having an annular shape when viewed in the axial direction, and a plurality of slots 12 that is provided on the inner radial side of the back yoke 11 and that extends in the axial direction. The stator core 10 is provided with a plurality of teeth 13 on both sides of each slot 12 in the circumferential direction.

Each slot 12 is a portion surrounded by a wall portion 11 a of the back yoke 11 provided on the outer radial side and a circumferential side surface 13 a of the two teeth 13. The slot 12 is provided with an opening portion 12 a that opens to the inner radial side. The slot 12 opens on both sides in the axial direction. The teeth 13 are formed so as to protrude radially inward from the back yoke 11, and a protruding portion 13 b configuring an opening portion 12 a of the slot 12 is formed on a distal end portion on the inner radial side. The wall portion 11 a and the circumferential side surface 13 a are examples of an “end surface of the armature core” in the claims.

The opening portion 12 a has an opening width W1 in the circumferential direction. Here, the opening width W1 corresponds to the distance between the distal end portions of the protruding portions 13 b of the teeth 13. A width W2 of a part of the slot 12 in which the coil portion 30 is disposed is larger than the opening width W2. That is, the slot 12 is configured as a semi-open type slot. Here, the width W2 corresponds to the distance between the circumferential side surfaces 13 a of the teeth 13 disposed on both sides of the slot 12 in the circumferential direction. The width W2 of the slot 12 is substantially constant in the radial direction.

(Structure of Coil Portion)

As shown in FIG. 5, the coil portion 30 is configured of a flat conductor wire. In the first embodiment, the coil portion 30 is configured of a material having a thermal expansion coefficient K2 larger than the thermal expansion coefficient K1 (linear expansion coefficient) of the stator core 10. For example, the coil portion 30 (conductor body 40 c) is made of copper or aluminum having the thermal expansion coefficient K2 larger than the thermal expansion coefficient K1.

As shown in FIGS. 2 and 3, the coil portion 30 is formed by the first coil assembly 30 a provided on one axial side (arrow Z2 direction side) and the second coil assembly 30 b provided on the other axial side (arrow Z1 direction side) being combined in the axial direction and joined. The first coil assembly 30 a and the second coil assembly 30 b are each formed in an annular shape centered around the same central axis C1 (see FIG. 1) as the stator core 10. As shown in FIG. 5, in the first embodiment, the coil portion 30 is formed by joining in a joint portion 90, a first leg portion 71 and a second leg portion 81, described below, of the segment conductors 40. The first leg portion 71 is an example of a “short leg portion” in the claims. The second leg portion 81 is an example of a “long leg portion” in the claims.

The coil portion 30 is configured as a wave winding coil, for example. Moreover, the coil portion 30 is configured as a coil of eight turns. That is, the coil portion 30 is configured so that eight segment conductors 40 are disposed in parallel in the slot 12 in the radial direction.

<Configuration of Wiring Connection of Coil Portion>

As shown in FIG. 6, the coil portion 30 is configured to generate magnetic flux by being supplied with three-phase alternating current power from a power supply unit (not shown). Specifically, the coil portions 30 are connected (wired) by three-phase Y-connection. That is, the coil portion 30 includes a U-phase coil portion 30U, a V-phase coil portion 30V, and a W-phase coil portion 30W. The coil portion 30 is provided with a plurality of (for example, two) neutral points N. Specifically, the coil portion 30 is connected in four parallel lines (star connection). That is, the U-phase coil portion 30U is provided with four neutral point connection end portions NtU and four power line connection end portions PtU. The V-phase coil portion 30V is provided with four neutral point connection end portions NW and four power line connection end portions PtV. The W-phase coil portion 30W is provided with four neutral point connection end portions NtW and four power line connection end portions PtW. In the following description, when the U-phase, the V-phase, and the W-phase are not particularly distinguished for the neutral point connecting end portion and the power line connecting end portion, the neutral point connecting end portion and the power line connecting end portion are simply indicated as a “neutral point connecting end portion Nt” and a “power line connection end portion Pt”.

<Configuration of Coil Assembly>

As shown in FIG. 3, the first coil assembly 30 a is composed of a plurality of first conductors 70 serving as the segment conductors 40. It is preferable that the first coil assembly 30 a be configured by combining only the first conductors 70.

As shown in FIG. 7, the second coil assembly 30 b includes a plurality of (for example, three) power segment conductors 50 (hereinafter, referred to as ‘power conductors 50_) as the segment conductors 40, and a plurality of (for example, two) neutral-point segment conductors 60 (hereinafter referred to as ‘neutral-point conductors 60_) as the segment conductors 40, and second conductors 80 that are conductors (general segment conductors 40) different from the power conductors 50 and the neutral-point conductors 60 among the segment conductors 40 and that configure the coil portion 30. That is, all of the power conductors 50 and the neutral point conductors 60 provided in the stator 100 are provided in the second coil assembly 30 b. The power conductors 50 and the neutral point conductors 60 are examples of a “second segment conductor” in the claims. The first conductors 70 are an example of a “first segment conductor” in the claims. The second conductors 80 are an example of the “second segment conductor” in the claims.

(Configuration of Segment Conductor)

As shown in FIG. 8, the segment conductor 40 is configured as a flat conductor wire having a substantially rectangular cross section. A conductor surface 40 b of the segment conductor 40 is provided with an insulating coating 40 a that has a thickness t1 and that is different from an insulating layer 20 a described later. The insulating layer 20 a is provided between the leg portions (71, 81) covered by the insulating coating 40 a and the stator core 10 (the wall portion 11 a and the circumferential side surface 13 a). The thickness t1 of the insulating coating 40 a is set, for example, to such an extent that interphase insulating performance (insulation between the first coil end portions 72 and insulation between the second coil end portions 82 (see FIG. 2)) can be ensured. Note that, in FIG. 8, the size relationship such as the thickness is highlighted for the sake of explanation, and the present disclosure is not limited to this example indicated in the drawing.

<Structure of First Conductor and Second Conductor>

As shown in FIGS. 9 and 10, the segment conductors 40 include the first conductors 70 disposed on one axial side (Z2 direction side) of the stator core 10 and the second conductors 80 that are disposed on the other axial side (Z1 direction side) of the stator core 10 and that face the first conductors 70 in the central axis direction. That is, the coil portion 30 is formed by joining the first conductors 70 and the second conductors 80, which are divided into two in the axial direction. Here, the second conductors 80 are the segment conductors 40 other than the power conductors 50 and the neutral point conductors 60 among the segment conductors 40 that configure the second coil assembly 30 b. Then, in the first embodiment, the power conductor 50, the neutral point conductor 60, and the first conductor 70 include the first leg portion 71 having a first length L1 in the axial direction. Each second conductor 80 include the second leg portion 81 that is disposed on the Z1 direction side of the first leg portion 71 and that has a second length L2 that is greater than the first length L1 in the axial direction.

In the first embodiment, as shown in FIG. 9, the first conductors 70 are formed so as to have a U-shape (substantially U-shape) when viewed in the radial direction by connecting a pair of the first leg portions 71 in which the first leg portions 71 are disposed in the slots 12 different from each other. The coil pitch of the first conductors 70 is six. That is, the first leg portions 71 of the pair of first leg portions 71 are disposed at positions different in the circumferential direction by six slots 12. That is, five slots 12 are provided between the slot 12 in which one first leg portion 71 of the pair of first leg portions 71 is disposed and the slot 12 in which the other first leg portion 71 of the pair of first leg portions 71 is disposed. Specifically, each first conductor 70 includes the pair of the first leg portions 71 that are disposed in different slots 12 and that are each linearly formed along the axial direction, and a first coil end portion 72. The first leg portion 71 means a portion disposed in the slot 12 from the axial position of the end surface 10 a (see FIG. 2) of the stator core 10. The first coil end portion 72 means a portion that is formed to be continuous with the first leg portion 71 and that is disposed on the outer axial side of the end surface 10 a of the stator core 10. The first coil end portion 72 has a bent shape that bends in the axial direction. Further, the first coil end portion 72 has a first crank part 73 formed in a crank shape in which the first crank part 73 is bent in a stepwise manner by the width of one segment conductor 40 in the radial direction when viewed in the axial direction. That is, the radial width of the first crank part 73 is twice the width of one segment conductor 40.

Further, the axial lengths L1 of the pair of first leg portions 71 are substantially equal to each other. The axial length L1 of the first leg portions 71 means the length from the most distal end of the first leg portion 71 to the bent part connected to the first coil end portion 72. The axial length L1 is smaller than an axial length L3 of the stator core 10 (see FIG. 2). The axial length L3 of the stator core 10 means the distance (interval) between the end surface 10 a and the end surface 10 b in the axial direction.

Similarly, as shown in FIG. 10, the second conductor 80 includes the pair of second leg portions 81 disposed in the slot 12 and the second coil end portion 82. The second coil end portion 82 also has a second crank part 83. In the first embodiment, the second conductor 80 is formed to have a U-shape by connecting the pair of second leg portions 81, which is disposed in the different slots 12, to each other. The axial lengths L2 of the pair of second leg portions 81 of the second conductor 80 are substantially equal to each other. Further, the axial length L2 of the pair of second leg portions 81 of the second conductor 80 is larger than the axial length L1 of the pair of first leg portions 71 of the first conductor 70 (L2>L1). The axial length L2 of the second leg portions 81 means the length from the most distal end of the second leg portions 81 to the bent part connected to the second coil end portion 82.

<Configuration of Power Conductor>

As shown in FIG. 11, in the power conductor 50, a plurality (for example, four) of the power line connection end portions Pt of the same phase are electrically connected to each other, and a plurality of the connected power line connection end portions Pt and one power terminal member 51 are electrically connected. In the power conductor 50, the second leg portion 81 joined to one of the pair of first leg portions 71 (see FIG. 14) and the power terminal member 51 are joined. The power conductor 50 has a function of introducing electric power into the coil portion 30 from the power supply unit (not shown).

Specifically, the power conductor 50 includes an outer radial side power conductor 52 that is disposed on the outer radial side of the slot 12 (see FIG. 1) and that has the power line connection end portion Pt, and an inner radial side power conductor 53 that is disposed on the inner radial side and the outer axial side of the outer radial side power conductor 52 and that has the power line connection end portion Pt. In other words, the power conductor 50 is formed in a bifurcated shape.

The outer radial side power conductor 52 and the power terminal member 51 are electrically connected by a lead wire 54. The inner radial side power conductor 53 and the power terminal member 51 are electrically connected to each other by the lead wire 54. The outer radial side power conductor 52 and the inner radial side power conductor 53 are electrically connected via the power terminal member 51 and the lead wire 54. The lead wire 54 is formed of a stranded wire (conductor) and an insulating tube 51 a is disposed on the outer circumference, for example.

The outer radial side power conductor 52 and the inner radial side power conductor 53 are each provided with the second leg portion 81 but are not provided with the first coil end portion 72 or the second coil end portion 82. Further, in the outer radial side power conductor 52 and the inner radial side power conductor 53, the lead wire 54 and the second leg portion 81 are joined via a conductor plate 55. For example, the joining is performed by brazing or welding (for example, any one of resistance welding, arc welding, laser welding, or high energy beam welding).

<Structure of Neutral Point Conductor>

As shown in FIG. 1, the neutral point conductor 60 includes an outer radial side neutral point conductor 61 and an inner radial side neutral point conductor 62. As shown in FIG. 6, the outer radial side neutral point conductor 61 and the inner radial side neutral point conductor 62 each include the neutral point N, and the neutral point connecting end portion NtU of the U-phase coil portion 30U, the neutral point connection end portion NW of the V-phase coil portion 30V, and the neutral point connection end portion NtW of the W-phase coil portion 30W are electrically connected.

As shown in FIG. 12, each outer radial side neutral point conductor 61 includes two U-phase W-phase neutral point segment conductors 61 a and two V-phase neutral point segment conductors 61 b. The U-phase W-phase neutral point segment conductors 61 a include the U-phase second leg portions 81 connected to the first leg portions 71 of the first conductors 70 for the U-phase among the three-phase alternating current, the W-phase second leg portions 81 connected to the W-phase first leg portions 71, and two neutral point coil end portions 61 c that each connect the U-phase second leg portion 81 and the W-phase second leg portion 81. The neutral point coil end portion 61 c is formed to be continuous with the U-phase second leg portion 81 and is formed to be continuous with the W-phase second leg portion 81.

The U-phase W-phase neutral point segment conductor 61 a is formed to have a substantially U-shape (substantially U-shape) when viewed from the inner radial side. The V-phase neutral point segment conductor 61 b is formed in a substantially linear shape when viewed from the inner radial side.

As shown in FIG. 1, the neutral point coil end portion 61 c is formed along the circumferential direction on the outer radial side of the second coil end portion 82 of the second conductor 80. The neutral point coil end portion 61 c is formed in a substantially arc shape when viewed in the arrow Z2 direction. One of the two U-phase W-phase neutral point segment conductors 61 a is disposed on the other outer axial side (arrow Z1 direction side).

As shown in FIG. 12, the V-phase neutral point segment conductor 61 b includes a V-phase second leg portion 81 connected to the V-phase first conductor 70 and a neutral point coil end portion 61 d. The neutral point coil end portion 61 d is formed so as to protrude from the second leg portion 81 in the outer axial direction (in the arrow Z1 direction). The two neutral point coil end portions 61 d are electrically joined to each other by being joined to both of the two neutral point coil end portions 61 c.

As shown in FIG. 13, the inner radial side neutral point conductor 62 includes two U-phase W-phase neutral point segment conductors 62 a and two V-phase neutral point segment conductors 62 b. The U-phase W-phase neutral point segment conductors 62 a include the U-phase second leg portions 81 connected to the first leg portions 71 of the first conductors 70 for the U-phase among the three-phase alternating current, the W-phase second leg portions 81 connected to the W-phase first conductor 70, and the neutral point coil end portions 62 c that each connect the U-phase second leg portion 81 and the W-phase second leg portion 81. The neutral point coil end portions 62 c are formed to be continuous with the U-phase second leg portions 81 and to be continuous with the W-phase second leg portion 81. As a result, the U-phase W-phase neutral point segment conductors 62 a are formed in a substantially U-shape (substantially U -shape) when viewed from the inner radial side. The V-phase neutral point segment conductors 62 b are formed in a substantially linear shape when viewed from the inner radial side.

As shown in FIG. 14, the neutral point coil end portion 62 c is formed so as to protrude axially outward with respect to the second coil end portion 82 of the second conductor 80. The neutral-point coil end portion 62 c is disposed close to the outer axial side of the second coil end portion 82 of the second conductor 80, and is formed along the circumferential direction when viewed in the axial direction. One of the two U-phase W-phase neutral point segment conductors 62 a is disposed on outer radial side of the other U-phase W-phase neutral point segment conductor 62 a.

The V-phase neutral point segment conductor 62 b includes the V-phase second leg portion 81 connected to the first leg portion 71 of the V-phase first conductor 70, and a neutral point coil end portion 62 d. The neutral point coil end portion 62 d is formed so as to protrude from the second leg portion 81 in the outer axial direction (in the direction of the arrow Z1). The two neutral point coil end portions 62 d are electrically joined by being joined to both of the two neutral point coil end portions 62 c.

(Structure of Joint Portion)

As shown in FIG. 14, the plurality of first conductors 70 and the plurality of second conductors 80 are joined in one slot 12. Further, in the first embodiment, the axial length L2 of the pair of second leg portions 81 of the second conductor 80 is larger than the axial length L1 of the pair of first leg portions 71 of the first conductor 70 (L2>L1). Thus, the joining portion 90 in which the first conductor 70 and the second conductor 80 are joined is disposed in the slot 12, on one end portion side (near the end surface 10 a) of the axial center of the stator core 10. Further, in all the slots 12 of the stator core 10, the joint portion 90 is provided in the vicinity of the end surface 10 a on one axial side. Here, the vicinity of the end surface 10 a includes, in the axial direction, the position that is on the Z2 direction side of the axial center C2 and that is the same position as the end surface 10 a, and the range within the substantially insulating creepage distance in the Z1 direction or the Z2 direction from the end surface 10 a, for example.

Further, in the first embodiment, the plurality of first leg portions 71 are provided in one slot 12 so as to be adjacent to each other in the radial direction of the stator core 10. That is, the joint portions 90 of the first leg portions 71 and the second leg portions 81 are disposed adjacent to each other in the radial direction in one slot 12.

<Configuration of Inclined Surface>

As shown in FIG. 15, the first conductor 70 of the plurality of segment conductors 40 is provided with a first facing surface 74, which is inclined with respect to a plane orthogonal to the axial direction, at the distal end portion of the first leg portion 71. In addition, the second conductor 80 is provided with a second facing surface 84, which is inclined with respect to the plane orthogonal to the axial direction, at the distal end portion of the second leg portion 81. The joining portion 90 is formed by joining the first facing surface 74 and the second facing surface 84, which face each other in the radial direction, of the first conductor 70 and the second conductor 80 which face each other in the axial direction. That is, the joint portion 90 means a portion in which the first conductor 70 and the second conductor 80 are joined. The first facing surface 74 and the second facing surface 84 are examples of an “inclined surface” in the claims.

Specifically, the first leg portion 71 includes the first facing surface 74 that faces the second leg portion 81 and that also faces the inner radial side (arrow R1 direction side). In addition, the second leg portion 81 includes the second facing surface 84 that faces the first facing surface 74 and that also faces the outer radial side (arrow R2 direction side). The first conductor 70 and the second conductor 80 are joined by joining the first facing surface 74 of the first leg portion 71 and the second facing surface 84 of the second leg portion 81.

Further, the first facing surface 74 of the first leg portion 71 and the second facing surface 84 of the second leg portion 81 are joined by a joining material (not shown), for example. The joining material joins and electrically connects the first facing surface 74 and the second facing surface 84. Specifically, the bonding material includes a conductive material such as silver or copper. It is preferable that the joining material is a paste form joining material (silver nanopaste) that contains, as conductive particles, metal particles obtained by miniaturizing silver to a nanometer level, in a solvent. Further, the bonding material contains a member (resin member) that volatilizes when heated, and has a function of bringing the first facing surface 74 and the second facing surface 84 close to each other by heating the volatilizing member and decreasing the volume of the bonding material.

As shown in FIG. 15, in the first embodiment, the joint portions 90, each in which the first conductor 70 and the second conductor 80 are joined, are configured so that the joint portions 90 adjacent in the radial overlap with each other when viewed in the radial direction. Specifically, the plurality of (all) joint portions 90 disposed in one slot 12 are configured to overlap with each other when viewed in the radial direction. That is, all the joint portions 90 disposed in one slot 12 are disposed in a state in which the joint portions 90 are aligned along the horizontal direction. In other words, each position of the joint portions 90 in the axial direction in one slot 12 are substantially equal to each other. The joining portion 90 is a part in which the first facing surface 74 of the first leg portion 71 and the second facing surface 84 of the second leg portion 81 are joined (overlapped) when viewed in the radial direction.

(Configuration of First Insulating Member)

As shown in FIG. 5, the first insulating member 20 is disposed between the wall portion 11 a and the teeth 13 and the first leg portion 71 and the second leg portion 81 (segment conductor 40). As shown in FIG. 16, the first insulating member 20 has a three-layer configuration. Specifically, as shown in FIG. 14, in the first embodiment, the first insulating member 20 includes, in the slot 12: an insulating layer 20 a that is provided between the wall portion 11 a of the back yoke 11 and the circumferential side surface 13 a of the teeth 13 (see FIG. 5), and the first leg portion 71 and the second leg portion 81, and that insulates the wall portion 11 a and the circumferential side surface 13 a from the first leg portion 71 and the second leg portion 81; and a fixing layer 20 c that is provided so as to overlap with a part 20 b at a position (region) (P2) different from the position P1 in the axial direction corresponding to the joining portion 90 among the insulating layer 20 a and that fixes the stator core 10 and the second leg portion 81. The fixing layer 20 c is preferably configured as an adhesive layer containing an adhesive. In addition, the position P2 includes, in the axial direction, the entire region inside the slot 12 of the part excluding the axial position P1, and a part near the end surface 10 b of the stator core 10 (including the part outside the slot 12 in the axial direction) for example. The insulating layer 20 a and the fixing layer 20 c are examples of a ‘first insulating layer_ and a ‘first fixing layer_ in the claims, respectively.

And the first insulating member 20 is disposed so as to integrally cover the surroundings of the second leg portions 81 disposed in parallel in the radial direction when viewed in the arrow Z2 direction. In other words, both sides in the circumferential direction and both sides in the radial direction of the second leg portions 81 disposed in parallel in the radial direction are covered by the first insulating member 20. In this way, the first insulating member 20 can ensure the insulation between the joint portion 90 and the stator core 10.

The insulating layer 20 a is configured of a poly phenylene sulfide resin (PPS), for example. The insulating layer 20 a may be formed in a non-woven fabric form such as aramid paper. In addition, in the first embodiment, as shown in FIG. 14, the insulating layer 20 a is provided from the end surface 10 a on one axial side of the stator core 10 across to the end surface 10 b on the other axial side. That is, the insulating layer 20 a is disposed so as to cover the wall portion 11 a and the circumferential side surface 13 a in each slot. In addition, to “cover” does not only mean to cover all parts of the wall portion 11 a and the circumferential side surface 13 a, but means a broad concept including a case in which the inner radial side part (distal end gap part) of the circumferential side surface 13 a is exposed, as shown in FIG. 5.

As shown in FIG. 16, in the first embodiment, the fixing layer 20 c includes a foaming agent 20 d (expanding agent) that foams due to heat. Specifically, the fixing layer 20 c is formed, for example, by mixing a plurality of capsule bodies as the foaming agent 20 d with a thermosetting resin 20 e. The foaming agent 20 d is configured to expand the volume of the capsule body when heated to a foaming temperature T1 or higher. The thickness of the fixing layer 20 c increases from t2 (see FIGS. 17) to t3 (see FIG. 18) by being heated in the manufacturing process of the stator 100, for example. As a result, the fixing layer 20 c fills the space between the second leg portion 81 and the wall portion 11 a and the circumferential side surface 13 a by the foaming agent 20 d foaming (expanding) when heated. The foaming agent 20 d is an example of a “first foaming agent” in the claims.

Further, the thermosetting resin 20 e is configured to be cured by being heated to a curing temperature T2 or higher which is higher than the foaming temperature T1. The thermoset ng resin 20 e forming the fixing layer 20 c is, for example, an epoxy resin. The fixing layer 20 c is configured so that when the fixing layer 20 c is heated, the thermosetting resin 20 e is cured so that the second leg portion 81 and the wall portion 11 a and the circumferential side surface 13 a are bonded and fixed.

As shown in FIG. 14, in the first embodiment, the fixing layer 20 c containing the foaming agent 20 d in the foamed state is filled between at least a part of the second leg portion 81, and the wall portion 11 a and the circumferential side surface 13 a that configure the slot 12, at the position P2 different from the position P1 in the axial direction corresponding to the joint portion 90. Specifically, in the first embodiment, the fixing layer 20 c is provided so as to overlap with the part 20 b of the insulating layer 20 a on the other axial side (Z1 direction side) of the position P1 in the axial direction corresponding to the joint portion 90. In other words, the fixing layer 20 c is provided so as to overlap with the part 20 b of the insulating layer 20 a on the other axial side of the vicinity of the end surface 10 a on the one axial side (Z2 direction side). Further, the fixing layer 20 c is provided in the slot 12 so as to overlap with the part 20 b of the insulating layer 20 a that is disposed between the second leg portion 81 and the stator core 10. For example, as shown in FIG. 16, the fixing layer 20 c is provided so as to overlap with and sandwich the insulating layer 20 a in the part 20 b of the insulating layer 20 a at a position different from the axial position corresponding to the joint portion 90.

Further, in the first embodiment, as shown in FIG. 15, the first insulating member 20 provided between the slot 12 and the coil portion 30 and the second insulating member 21 provided separately from the first insulating member 20 are provided. As shown in FIG. 19, the joint portions 90 in which the first conductor 70 and the second conductor 80 are joined between the coils adjacent in the radial direction in one slot 12 are insulated by the second insulating member 21 that is provided separate from the first insulating member 20. The term ‘coils adjacent in the radial direction_ means a linear part of the coil portion 30 that is disposed in the slot 12 after the first conductor 70 and the second conductor 80 are joined.

Here, in the first embodiment, as shown in FIG. 19, the second insulating member 21 is formed by folding one sheet-shaped insulating member such as a Nomex. The second insulating member 21 includes: a facing surface insulating part 21 a that covers facing surfaces 90 a of the joint portions 90 that are adjacent in the radial direction; and a circumferential surface insulating part 21 b that is continuous from end portions of the facing surface insulating part 21 a in the circumferential direction and that covers one of the circumferential surfaces 90 b of the joint portion 90 that are adjacent in the radial direction for at least the insulation distance. The facing surface 90 a of the joint portion 90 means an outer radial surface and an inner radial surface, which face each other, of the joint portions 90 that are radially adjacent to each other. The insulation distance means a distance (creepage distance) that is a length along the circumferential surface insulating part 21 b in the radial direction and that is sufficient for insulating the joint portions 90, which are adjacent to each other, from each other.

As shown in FIG. 20, the second insulating member 21 includes a part 21 c that covers an outer radial side of the joint portion 90 disposed on the outermost radial side, and a part 21 d that covers the inner dial side of the joint portion 90 disposed on the innermost radial side.

Further, in the second insulating member 21, the facing surface insulating parts 21 a that are adjacent in the radial direction are connected to each other by the circumferential surface insulating part 21 b in one or the other circumferential direction. Specifically, the facing surface insulating part 21 a on the outer radial side among the pair of facing surface insulating parts 21 a disposed adjacent to each other in the radial direction, the circumferential surface insulating part 21 b provided on one side in the circumferential direction, the facing surface insulating part 21 a on the inner radial side among the pair of facing surface insulating parts 21 a, and the circumferential surface insulating part 21 b provided on the other side in the circumferential direction are formed to be continuous. That is, the circumferential surface 90 b on the A1 direction side of the joint portion 90 and the circumferential surface 90 b on the A2 direction side of the joint portion 90 are alternately covered by the circumferential surface insulating part 21 b. In other words, the second insulating member 21 is configured so as not to continuously cover the circumferential surfaces 90 b of the plurality of joint portions 90 disposed adjacent to each other in the radial direction.

Thus, the second insulating member 21 has a meandering shape (bellows shape) when viewed from the central axis direction. Further, all the joint portions 90 disposed in one slot 12 are insulated from each other by one second insulating member 21. This makes it possible to reduce the number of steps for disposing the second insulating member 21 as compared to the case in which the plurality of joint portions 90 disposed in one slot 12 are individually covered by the insulating member.

Further, in the first embodiment, as shown in FIG. 20, the second insulating member 21 is configured to be expandable/contractible along the radial direction. The second insulating member 21 is made of a flexible sheet-shaped insulating member, and is configured to not continuously cover the circumferential surfaces 90 b of the plurality of joint portions 90 disposed adjacent to each other in the radial direction. Thus, even when the first leg portion 71 and the second leg portion 81 are pressed in the radial direction or the axial direction when the first leg portion 71 and the second leg portion 81 are joined, the second insulating member 21 can be deformed with the movement of the first leg portion 71 and the second leg portion 81.

Further, as shown in FIG. 15, the second insulating member 21 is disposed so that an edge portion on one axial side protrudes outward from the end surface 10 a of the stator core 10 in the central axis direction. Specifically, in the central axis direction, the Z2 direction side of the second insulating member 21 protrudes outward from the end surface 10 a of the stator core 10, and the Z1 direction side is disposed in the slot 12.

Further, as shown in FIG. 15, the first insulating member 20 is also disposed together with the second insulating member 21 so as to protrude outward from the end surface 10 a of the stator core 10 in the central axis direction. A height position h1 of the part of the second insulating member 21 protruding outward from the end surface 10 a of the stator core 10 and a height position h2 of the part of the first insulating member 20 protruding outward from the end surface 10 a of the stator core 10 are substantially equal. The protruding amount of the first insulating member 20 and the second insulating member 21 from the end surface 10 a of the stator core 10 is adjusted to a degree in which the first insulating member 20 and the second insulating member 21 are not bent by coming into contact with the second coil end portion 82 of the second segment conductor 80.

Further, as shown in FIG. 3, a length L12 of the second insulating member 21 is smaller than a length L11 of the first insulating member 20 in the central axis direction. Specifically, the length L11 of the first insulating member 20 is larger than the length L3 of the stator core 10 in the central axis direction. The length L12 of the second insulating member 21 is smaller than the length L3 of the stator core 10. The second insulating member 21 is provided so as to cover the joint portion 90 and extend from the joint portion 90 toward the Z1 direction side and the Z2 direction side. The length L12 of the second insulating member 21 is adjusted based on the magnitude of the voltage applied to the coil portion 30 (based on the required creepage distance).

Further, since the length L12 of the second insulating member 21 is smaller than the length L11 of the first insulating member 20, as shown in FIG. 21, the first insulating member 20 has a part 20 f that overlaps with the second insulating member 21 and the part 20 b that does not overlap with the second insulating member 21 when viewed in the radial direction. Specifically, the first insulating member 20 overlaps with the second insulating member 21 in the vicinity of the end portion (end surface 10 a) in the central axis direction in the slot 12. A thickness t11 of the part 20 f of the first insulating member 20 that overlaps with the second insulating member 21 is smaller than a thickness t12 of the part 20 b of the first insulating member 20 that does not overlap with the second insulating member 21.

A thickness t13 of the second insulating member 21 is smaller than the thickness t11. Further, the thickness t12 is obtained by adding the thickness t11 to the thickness t3 of two sheets (t3B2) of the fixing layer 20 c.

Here, in the first embodiment, the fixing layer 20 c is not provided and a clearance C11 is provided, between the joint portion 90 (see FIG. 14) and the stator core 10 (the wall portion 11 a and the circumferential side surface 13 a). Further, the fixing layer 20 c is provided between a part of the second leg portion 81 (see FIG. 14) other than the joint portion 90 (that is, a part of the second leg portion 81 on the end surface 10 b side with respect to the joint portion 90) and the stator core 10 (the wall portion 11 a and the circumferential side surface 13 a). Specifically, the clearance C11 is a clearance formed by the difference between the thickness t12 of the part 20 b and the thickness t11 of the part 20 f. Although only the clearance C11 between the wall portion 11 a and the joint portion 90 is shown in FIG. 21, since the same applies to the circumferential side surface 13 a, illustration is omitted.

Further, in the first embodiment, the second insulating member 21 is disposed on one axial side (Z2 direction side) with respect to the fixing layer 20 c of the first insulating member 20 and between the joint portions 90 in the radial direction, and is configured to insulate the joint portions 90 from each other. Specifically, the fixing layer 20 c is provided so as to overlap with the part 20 b of the insulating layer 20 a that does not overlap with the second insulating member 21 in the radial direction. Further, the insulating layer 20 a is disposed in the part 20 f that overlaps with the second insulating member 21 when viewed in the radial direction.

Second Embodiment

Next, with reference to FIG. 4 and FIGS. 22 to 32, a stator 200 according to a second embodiment will be described. In the stator 200 of the second embodiment, insulating members (121, 122) that are integrally formed are provided, unlike the stator 100 of the first embodiment that has the first insulating member 20 and the second insulating member 21 that are provided separately from each other. The same configurations as those in the first embodiment are indicated by the same reference numerals as those in the first embodiment and are shown in the drawings, and the description thereof will be omitted.

[Structure of Stator]

The structure of the stator 200 according to the second embodiment will be described with reference to FIG. 4 and FIGS. 22 to 31. The stator 200 is an example of the ‘armature_ in the claims.

As shown in FIG. 22, the stator 200 includes the sheet-shaped insulating member 121 and a coil portion 130. The coil portion 130 also includes a first coil assembly 130 a (non-lead side coil) and a second coil assembly 130 b (lead side coil). Further, the coil portion 130 is composed of a plurality of segment conductors 140 (see FIGS. 24A and 24B). The insulating member 121 is an example of a “second joint portion insulating member” in the claims.

In addition, as shown in FIG. 23, in the central axis direction, the insulating member 121 (contact portion insulating part 121 c described below) and the core leg portion insulating part 122 described below each have the same length L22. The length L22 is larger than the length L3 of the stator core 10 in the central axis direction. In FIG. 23, illustration of the first conductor 170 and the second conductor 180 is omitted for simplification. In addition, in FIG. 23, each shape of the insulating member 121 and the core leg portion insulating part 122 are schematically illustrated.

(Configuration of Segment Conductor)

As shown in FIGS. 24A and 24B, the segment conductor 140 is configured as a flat conductor wire having a substantially rectangular cross section. In the segment conductor 140, a first leg portion 171 (second leg portion 181), which will be described below, is not covered with the insulating coating and a conductor surface 140 b is exposed (see FIG. 24A). In contrast, in the segment conductor 140, an insulating coating 140 a (see FIG. 24B) having a thickness t21 is provided on the conductor surface 140 b of a first coil end portion 172 (second coil end portion 182) described below. For example, the thickness t21 of the insulating coating 140 a is set to ensure an interphase insulating performance (insulation between the first coil end portions 172 and insulation between the second coil end portions 182 (see FIGS. 25A and B, and FIGS. 26A and B)). In FIGS. 24A and 24B, for the sake of explanation, the magnitude relationship such as the thickness is emphasized. However, the present disclosure is not limited to this illustrated example. In FIGS. 24A and 24B, only the first conductor 170 described below is shown. However, the second conductor 180 is similar, illustration thereof is omitted. The conductor surface 140 b is an example of a “metal surface” in the claims.

<Structure of First Conductor and Second Conductor>

As shown in FIGS. 25A (B) and 26A (B), the plurality of segment conductors 140 includes a plurality of first conductors 170 disposed on one axial side (Z2 direction side) of the stator core 10 and a plurality of second conductors 180 disposed on the other axial side (Z1 direction side) of the stator core 10. The first conductor 170 and the second conductor 180 are disposed facing each other in the central axis direction. The first conductor 170 also includes the first leg portion 171 having a length L31 in the axial direction. The first leg portion 171 extends to the other side (Z1 direction side) in the central axis direction. The second conductor 180 also includes the second leg portion 181 having a length L32 in the axial direction. The second leg portion 181 extends to one side (Z2 direction side) in the central axis direction. The length L31 of the first leg portion 171 and the length L32 of the second leg portion 181 are substantially the same. Further, each of the first leg portion 171 and the second leg portion 181 is inserted in the slot 12. The first conductor 170 and the second conductor 180 are examples of a ‘third segment conductor_ and a ‘fourth segment conductor_ in the claims, respectively.

As shown in FIGS. 25A and 25B, the plurality of first conductors 170 is formed to have a U-shape (substantially U-shape) when viewed in the radial direction by connecting a pair of the first leg portions 171, which are disposed in different slots 12, to each other. The coil pitch of the first conductor 170 is six. That is, the first leg portions 171 are disposed at positions different in the circumferential direction by six slots 12. That is, five slots 12 are provided between the slot 12 in which one first leg portion 171 of the pair of first leg portions 171 is disposed and the slot 12 in which the other first leg portion 171 is disposed. Specifically, the first conductor 170 includes the pair of first leg portions 171, which are each disposed in different slots 12 and which are linearly formed along the axial direction, and the first coil end portion 172. The first leg portion 171 means a part disposed in the slot 12 from the axial position of the end surface 10 a (see FIG. 2) in the central axis direction of the stator core 10, and the first coil end portion 172 means a part that is formed to be continuous with the first leg portion 171 and that is disposed on the outer axial side of the end surface 10 a of the stator core 10. The first coil end portion 172 has a bent shape that bends in the axial direction. Further, the first coil end portion 172 has a first crank part 173 formed in a crank shape that is bent in a stepwise shape for a width of one segment conductor 140 in the radial direction when viewed in the axial direction. That is, the radial width of the first crank part 173 is twice the width of one segment conductor 140.

Further, the axial lengths L31 of the pair of first leg portions 171 are substantially equal to each other. An axial length L31 means the length of the part of the first conductor 170 that extends linearly in the central axis direction within the slot 12. The axial length L31 is smaller than the central axis direction length L3 (see FIG. 23) of the stator core 10 (slot 12).

Similarly, as shown in FIGS. 26A and 26B, the second conductor 180 includes a pair of the second leg portions 181 disposed in the slot 12 and the second coil end portion 182. Also, the second coil end portion 182 has a second crank part 183. The second conductor 180 is formed to have a U-shape by connecting the pair of second leg portions 181, which are disposed in different slots 12, to each other. The axial lengths L32 of the pair of second leg portions 181 of the second conductor 180 are substantially equal to each other. The axial length L32 means the length of the part of the second conductor 180 that extends linearly in the central axis direction within the slot 12.

As shown in FIG. 27, the plurality of first leg portions 171 are provided in each of the plurality of slots 12 so that the first leg portions 171 are adjacent to each other in the radial direction of the stator core 10. In addition, the plurality of second leg portions 181 are provided in each of the plurality of slots 12 so that the second leg portions 181 are adjacent to each other in the radial direction of the stator core 10.

Further, in one slot 12, a plurality of first surfaces 171 a provided on the first leg portions 171 and the second surfaces 181 a provided on the second leg portions 181 are disposed alternately along the radial direction. Each first surface 171 a is provided on a distal end portion 171 b side of the first leg portion 171. Each second surface 181 a is provided on a distal end portion 181 b side of the second leg portion 181. The first surface 171 a and the second surface 181 a are provided so as to be in contact with each other as described below, and the first surface 171 a and the second surface 181 a that are in contact with each other are disposed so as to face each other in the radial direction.

Further, the stator 200 includes a spring member 210 that is provided in each of the plurality of slots 12 so as to be sandwiched between the coil portion 130 and the opening portion 12 a (protruding portion 13 b) of the slot 12. That is, the spring member 210 is provided in a distal end clearance 12 b provided inside the slot 12 in the radial direction.

The spring member 210 is configured to press the coil portion 130 from the inner radial side of the coil portion 130 in the radial direction so that the first surface 171 a of the first leg portion 171 of the first conductor 170 and the second surface 181 a of the second leg portion 181 of the second conductor 180 are in contact with each other. A contact portion 190 is formed by contact between the first surface 171 a of the first leg portion 171 and the second surface 181 a of the second leg portion 181. The contact portion 190 is an example of a ‘joint portion_ in the claims.

The first surface 171 a and the second surface 181 a are in contact with each other by being pressed by the spring member 210 without a bonding agent being interposed between the first surface 171 a and the second surface 181 a. That is, the first surface 171 a and the second surface 181 a are not joined, and the contact state between the first surface 171 a and the second surface 181 a is maintained by the pressing force of the spring member 210.

In addition, a plurality of sets (eight in the second embodiment) of the first surface 171 a and the second surface 181 a that are in contact with each other are provided in one slot 12. T hat is, a plurality of the contact portions 190 is provided in one slot 12. The contact portions 190 are disposed adjacent to each other in the radial direction within one slot 12.

In addition, a plurality of sets (eight in the second embodiment) of the first surface 171 a and the second surface 181 a that are in contact with each other are provided in one slot 12. That is, a plurality of the contact portions 190 is provided in one slot 12. The contact portions 190 are disposed adjacent to each other in the radial direction within one slot 12.

Here, in the second embodiment, each of the plurality of contact portions 190 is disposed within the slot 12, in a central portion in the central axis direction of the stator core 10. The spring member 210 is also disposed in the central portion of the stator core 10 in the central axis direction. Specifically, the spring member 210 is provided so as to overlap with each of the plurality of contact portions 190 when viewed in the radial direction.

Further, each of the first surface 171 a and the second surface 181 a is plated. That is, the plated surfaces (the first surface 171 a and the second surface 181 a) are in contact with each other.

In the plating process, metals such as nickel (Ni), silver (Ag), gold (Au), and tin (Sn) are used. The plating process may be performed using a plurality of metals (for example, Ni and Ag) among the above metals.

As shown in FIG. 28, the first leg portion 171 includes a first surface forming portion 171 c in which the first surface 171 a is formed. The first surface forming portion 171 c (first surface 171 a) is provided so as to extend along the central axis direction. In addition, the first leg portion 171 includes a first leg body portion 171 d that is provided on one side (Z2 direction side) in the central axis direction of the first surface forming portion 171 c so as to be continuous from the first surface forming portion 171 c. The first surface forming portion 171 c has a radial thickness t31. The first leg body portion 171 d has a radial thickness t32. The radial thickness t32 of the first leg body portion 171 d is greater than the radial thickness t31 of the first surface forming portion 171 c.

Further, the first leg portion 171 includes a first step portion 171 e provided between the first surface forming portion 171 c and the first leg body portion 171 d. A clearance portion 171 f is provided between the first step portion 171 e and the distal end portion 181 b of the second leg portion 181.

The second leg portion 181 includes a second surface forming portion 181 c in which the second surface 181 a is formed. The second surface forming portion 181 c (second surface 181 a) is provided so as to extend along the central axis direction. In addition, the second leg portion 181 includes a second leg body portion 181 d that is provided on the other side (Z1 direction side) in the central axis direction of the second surface forming portion 181 c so as to be continuous from the second surface forming portion 181 c. The second surface forming portion 181 c has a radial thickness t33. The second leg body portion 181 d has a radial thickness t34. The radial thickness t34 of the second leg body portion 181 d is greater than the radial thickness t33 of the second surface forming portion 181 c.

The second leg portion 181 includes a second step portion 181 e provided between the second surface forming portion 181 c and the second leg portion main body portion 181 d. A clearance portion 181 f is provided between the second step portion 181 e and the distal end portion 171 b of the first leg portion 171.

The radial thickness t31 of the first surface forming portion 171 c and the radial thickness t33 of the second surface forming portion 181 c are substantially equal.

The radial thickness t32 of the first leg body portion 171 d and the radial thickness t34 of the second leg body portion 181 d are substantially equal. Note that, in FIG. 28, in order to highlight the insulating member 121, the insulating member 121 is illustrated so as to have a thickness greater than the actual thickness.

Here, in the second embodiment, as shown in FIG. 29, the sheet-shaped insulating member 121 is provided so as to insulate the contact portions 190 between the coils adjacent in the radial direction in one slot 12. That is, the insulating member 121 is provided so as to insulate the contact portions 190 from each other, in which the first leg portion 171 in which the conductor surface 140 b (see FIGS. 24A and 24B) is exposed and the second leg portion 181 in which the conductor surface 140 b is exposed are in contact with each other without interposing a bonding agent. Specifically, the insulating member 121 is provided between each of the plurality of (eight in the second embodiment) coils (a set of the first leg portion 171 and the second leg portion 181 that are in contact with each other) disposed in the radial direction in the slot 12.

Specifically, the insulating member 121 is formed by folding one sheet-shaped insulating member such as a Nomex. The insulating member 121 includes: facing surface insulating parts 121 a that cover facing surfaces 190 a of the contact portions 190 that are adjacent in the radial direction; and a circumferential surface insulating part 121 b that is continuous from both end portions of the facing surface insulating part 121 a in the circumferential direction and that covers one of the circumferential surfaces 190 b of the contact portions 190 that are adjacent in the radial direction for at least the insulation distance. The facing surfaces 190 a of the contact portions 190 mean an outer radial surface and an inner radial surface of the contact portions 190, which face each other in the radial direction. Further, the insulation distance is a length along the radial direction of the circumferential surface insulating part 121 b and means a distance (creepage distance) sufficient for insulating the contact portions 190 adjacent to each other in the radial direction. The circumferential surfaces 190 b mean surfaces of the contact portions 190 that intersect with the circumferential direction. In other words, the circumferential surfaces 190 b mean surfaces extending in the radial direction and the axial direction. The insulation distance is an example of a ‘predetermined distance_ in the claims.

In addition, the insulating member 121 includes the contact portion insulating parts 121 c that are formed so that the following are continuous: the facing surface insulating part 121 a on the outer radial side among a pair of the facing surface insulating parts 121 a disposed adjacent to each other in the radial direction; the circumferential surface insulating part 121 b provided on one circumferential side; the facing surface insulating part 121 a on the inner radial side among the pair of the facing surface insulating parts 121 a; and the circumferential surface insulating part 121 b provided on the other side in the circumferential direction.

Here, in the second embodiment, the stator 200 includes the core leg portion insulating part 122 that is provided between the slot 12 and the coil portion 130 and that is integrally formed with the contact portion insulating part 121 c. That is, the core leg portion insulating part 122 has a sheet shape similar to the contact portion insulating part 121 c and is made of the same material as the contact portion insulating part 121 c. Further, the contact portion insulating part 121 c and the core leg portion insulating part 122 have the same thickness (not shown). The contact portion insulating part 121 c and the core leg portion insulating part 122 have the same length L22 (see FIG. 27) in the central axis direction. The core leg portion insulating part 122 is an example of the “core leg portion fixing member” in the claims.

Specifically, the core leg portion insulating part 122 has the one side insulating part 122 a that is continuous with the facing surface insulating part 121 a on the outermost radial side and that is provided, on one side of the slot 12 in the circumferential direction (left side in FIG. 29), between the slot 12 (circumferential side surface 13 a) and the coil portion 130 (circumferential surface 190 b). Further, the core leg portion insulating part 122 has the other side insulating part 122 b that is continuous with the facing surface insulating part 121 a on the innermost radial side and that is provided, on the other side of the slot 12 in the circumferential direction (right side in FIG. 29), between the slot 12 (circumferential side surface 13 a) and the coil portion 130 (circumferential surface 190 b).

Specifically, the one side insulating part 122 a (other side insulating part 122 b) is provided so that a part sandwiched between the circumferential side surface 13 a and the circumferential surface 190 b, and a part sandwiched between the circumferential side surface 13 a and the circumferential surface insulating part 121 b that covers the circumferential surface 190 b are arranged alternately along the radial direction.

Further, in the second embodiment, the one side insulating part 122 a extends from an outer radial side end portion 230 a of the coil portion 130 in the slot 12 to an inner radial side end portion 230 b (so as to extend over the end portion 230 b). The other side insulating part 122 b extends from the inner radial side end portion 230 b of the coil portion 130 in the slot 12 to the outer radial side end portion 230 a (so as to extend over the end portion 230 a). That is, the coil portion 130 in the slot 12 is provided so as to be surrounded by the facing surface insulating part 121 a on the outermost radial side, the facing surface insulating part 121 a on the innermost radial side, the one side insulating part 122 a, and the other side insulating part 122 b.

The core leg portion insulating part 122 includes an inner radial side insulating part 122 c that is continuous with the one side insulating part 122 a and that is provided so as to cover the facing surface insulating part 121 a on the innermost radial side from the inner radial side. Further, the core leg portion insulating part 122 has an outer radial side insulating part 122 d that is continuous with the other side insulating part 122 b and that is provided so as to cover the facing surface insulating part 121 a on the outermost radial side from the outer radial side.

Specifically, the inner radial side insulating part 122 c is provided so as to be sandwiched between the facing surface insulating part 121 a on the innermost radial side and the spring member 210. That is, the coil portion 130 and the spring member 210 are insulated from each other by the facing surface insulating part 121 a on the innermost radial side and the inner radial side insulating part 122 c. The outer radial side insulating part 122 d is provided so as to be sandwiched between the facing surface insulating part 121 a on the outermost radial side and the wall portion 11 a of the slot 12.

That is, the coil portion 130 and the wall portion 11 a (stator core 10) of the slot 12 are insulated from each other by the facing surface insulating part 121 a on the outermost radial side and the outer radial side insulating part 122 d.

Further, the inner radial side insulating part 122 c has a length L41 in the circumferential direction. Further, the outer radial side insulating part 122 d has a length L42 in the circumferential direction. Each of the length L41 of the inner radial side insulating part 122 c and the length L42 of the outer radial side insulating part 122 d is greater than half the width W2 of the slot 12 (see FIG. 4), for example.

In the second embodiment, as shown in FIG. 27, the length L22 of each of the contact portion insulating part 121 c (see FIG. 29) and the core leg portion insulating part 122 (see FIG. 29) in the central axis direction is greater than a length L62 of the slot 12 in the central axis direction. The length L62 of the slot 12 in the central axis direction is equal to the length L3 of the stator core 10 in the central axis direction (see FIG. 22). In addition, each of the contact portion insulating part 121 c and the core leg portion insulating part 122 is disposed so that edge portions on both sides in the central axis direction protrude outward from the end surfaces (10 a, 10 b) of the stator core 10 in the central axis direction. As a result, each of the contact portion insulating part 121 c and the core leg portion insulating part 122 is provided across the entire slot 12, in the central axis direction.

Further, as shown in FIG. 30, the contact portion insulating part 121 c includes an insulating layer 123 a and a fixing layer 123 b that includes a foaming agent 123 c that foams due to heat. The foaming agent 123 c foams and expands so as to fix a coil (a pair in which the first leg portion 171 and the second leg portion 181 are in contact with each other) in at least the central axis direction with respect to a coil adjacent in the circumferential direction. The fixing layer 123 b is provided on both surfaces of the insulating layer 123 a. When the fixing layer 123 b is heated, a thermosetting resin 123 d is cured. As a result, the fixing layer 123 b of the contact portion insulating part 121 c bonds the adjacent coils to each other to fix the coils. In FIG. 30, illustration of the stator core 10 and the like is omitted for simplification. The insulating layer 123 a and the fixing layer 123 b are examples of a ‘second insulating layer_ and a ‘second fixing layer_ in the claims, respectively. The foaming agent 123 c is an example of a “second foaming layer” in the claims.

As shown in FIG. 31, the core leg portion insulating part 122 includes an insulating layer 124 a and a fixing layer 124 b that includes a foaming agent 124 c that foams due to heat. The foaming agent 124 c foams and expands so as to fix each of the first leg portion 171 and the second leg portion 181 in at least the central axis direction with respect to the stator core 10. The fixing layer 124 b of the core leg portion insulating part 122 is configured to bond and fix each of the first leg portion 171 and the second leg portion 181 to the stator core 10. In FIGS. 36 and 37, the insulating member 121 and the core leg portion insulating part 122 are illustrated to have a thickness larger than the actual thickness so as to highlight the insulating member 121 and the core leg portion insulating part 122. Since the insulating layer 123 a (124 a) and the fixing layer 123 b (124 b) have the same configurations (materials) as the insulating layer 20 a and the fixing layer 20 c of the first embodiment, detailed description thereof will be omitted. The insulating layer 124 a and the fixing layer 124 b are examples of the “first insulating layer” and the “first fixing layer” in the claims, respectively. The foaming agent 124 c is an example of the “first foaming layer” in the claims.

Here, in the second embodiment, the fixing layer 124 b (fixing layer 123 b, see FIG. 30) is provided so as to overlap with a part 124 e (part 123 e, see FIG. 30) of the insulating layer 124 a (insulating layer 123 a, see FIG. 30) at a position (P4, see FIG. 27) different from a position (P3, see FIG. 27) in the central axis direction corresponding to the contact portion 190. In other words, in the core leg portion insulating part 122 (contact portion insulating part 121 c, see FIG. 30), only the insulating layer 124 a (insulating layer 123 a) is provided at the position P3 in the central axis direction corresponding to the contact portion 190. Specifically, the fixing layer 124 b (fixing layer 123 b) is provided so as to be separated into two parts, which are a part on the one side (Z2 direction side) in the central axis direction with respect to the first step portion 171 e (see FIG. 36) and a part on the other side (Z1 direction side) in the central axis direction with respect to the second step portion 181 e (see FIG. 36). In addition, the position P4 includes, in the axial direction, the entire region inside the slot 12 of the part excluding the axial position P3 in the axial direction, and the near the end surface 10 b of the stator core 10 (including the part outside the slot 12 in the axial direction), for example.

That is, the fixing layer 124 b is not provided and a clearance C21 is provided, between the contact portion 190 and the circumferential side surface 13 a (wall portion 11 a) of the stator core 10. The fixing layer 124 b is provided between the leg portions (171, 181) other than the contact portion 190 and the circumferential side surface 13 a (wall portion 11 a) of the stator core 10. FIG. 31 shows only the clearance C21 between the circumferential side surface 13 a and the contact portion 190.

(Stator Manufacturing Process)

Next, with reference to FIG. 32, a manufacturing process of the stator 200 will be described.

As shown in FIG. 32, first, in step S1, the insulating member 121 (contact portion insulating part 121 c) and the core leg portion insulating part 122 are integrally inserted (placed) in the slot 12.

Next, in step S2, the second leg portion 181 (see FIG. 27) of the second conductor 180 is inserted in the slot 12 from the other side (Z1 direction side) in the central axis direction.

Next, in step S3, the first leg portion 171 (see FIG. 27) of the first conductor 170 is inserted in the slot 12 from one side (Z2 direction side) in the central axis direction. At this time, the first leg portion 171 is disposed so that the first surface 171 a of the first leg portion 171 and the second surface 181 a of the second leg portion 181 face each other.

Next, in step S4, the spring member 210 (see FIG. 27) is inserted in the slot 12 from the inner radial side through the opening portion 12 a of the slot 12.

Then, in step S5, the stator core 10 is heated and the fixing layer 123 b is heated and thus, the foaming agent 123 c is foamed and the fixing layer 123 b is expanded.

In this way, the coil portion 130 is fixed to the slot 12 at least in the central axis direction.

The other configurations of the second embodiment are the same as those of the first embodiment.

Effects of First and Second Embodiments

In the first and second embodiments, the following effects can be obtained.

In the first and second embodiments, as described above, the configuration is such that the first fixing layer (20 c, 124 b) of the core leg portion fixing member (20, 122) is provided in the part (20 b, 124 e) at the position (P2, P4) different from the position (P1) in the central axis direction corresponding to the joint portion (90, 190) so as to fix the armature core (10) and the leg portion (81, 171, 181). Thus, in the central axis direction, since the first fixing layer (20 c, 124 b) is not provided on the joint portion (90, 190), the relative positions of the joint portion (90, 190) and the armature core (10) is not fixed due to fixing by the first fixing layer (20 c, 124 b). Thus, even if the expansion length (contraction length) along the central axis direction of the armature core (10) and the expansion length (contraction length) along the center axis direction of the leg portion (71, 81, 171, 181) are different sizes due to the armature core (10) and the leg portion (71, 81, 171, 181) being heated or cooled, the thermal stress can be relaxed, since the relative positions of the joint portion (90, 190) and the armature core (10) in the central axis direction can be changed. Further, in the above embodiment, since the first fixing layer (20 c, 124 b) of the core leg portion fixing member (20, 122) is configured to fix the armature core (10) and the leg portion (81, 171, 181), there is no need to form the core leg portion fixing member (20, 122) by molding resin so that the segment conductor (40, 140) can be press-fitted to the core leg portion fixing member (20, 122). As a result, it is possible to prevent the manufacturing equipment of the armature (100, 200) from becoming complicated since resin molding is not required. As a result, it is possible to reduce the thermal stress on the joint portions (90, 190) of the leg portions (71, 81, 171, 181) of the plurality of segment conductors (40, 140) while preventing the manufacturing equipment of the armature (100, 200) from becoming complicated. The term ‘joint portion (90, 190)_ has a broad meaning including not only the part joined via the bonding agent but also the part that is only in contact without the bonding agent.

In the first and second embodiments, as described above, the first fixing layer (20 c, 124 b) contains a first foaming agent (20 d, 124 c) that foams due to heat, and at a position (P2, P4) different from the position (P1, P3) in the central axis direction corresponding to the joint portion (90, 190), the first fixing layer (20 c, 124 b) containing the first foaming agent (20 d, 124 c) in a foamed state is filled between an end surface (11 a, 13 a) of the armature core (10) and the leg portion (81, 171, 181). With such a configuration, the segment conductor (40, 140) can be disposed in the slot (12) after the core leg portion fixing member (20, 122) having the first fixing layer (20 c, 124 b) containing the first foaming agent (20 d, 124 c) in a non-foamed state is disposed in the slot (12). Thus, between the end surface (11 a, 13 a) of the armature core (10) and the leg portion (81, 171, 181), the leg portion (81, 171, 181) can be inserted in the slot (12) while the thickness (t2) of the first fixing layer (20 c, 124 b) is made relatively small to prevent the leg portion (81, 171, 181) and the core leg portion fixing member (20, 122) from mechanically interfering. As a result, insertability of the leg portion (81, 171, 181) into the slot (12) can be improved. When the first foaming agent (20 d, 124 c) of the first fixing layer (20 c, 124 b) is foamed after the leg portion (81, 171, 181) is disposed in the slot (12), it is possible to increase the thickness of the core leg portion fixing member (20, 122) (to t3) so as to fill the space between the leg portion (81, 171, 181) and the end surface (11 a, 13 a) of the armature core (10). As a result, it is possible to improve the fixing strength and the insulating performance of the leg portion (81, 171, 181) with respect to the armature core (10) while improving the insertability of the leg portion (81, 171, 181) into the slot (12).

Further, in the first and second embodiments, as described above, the core leg portion fixing member (20, 122) further includes a first insulating layer (20 a, 124 a) that is provided in the slot (12), between the end surface (11 a, 13 a) of the armature core (10) and the leg portion (71, 81, 171, 181), and that insulates the end surface (11 a, 13 a) of the armature core (10) and the leg portion (71, 81, 171, 181). The first fixing layer (20 c, 124 b) is provided so as to overlap with a part (20 b, 124 e) of the first insulating layer (20 a, 124 a) at a position (P2, P4) different from the position (P1, P3) in the central axis direction corresponding to the joint portion (90, 190). With such a configuration, it is possible to ensure insulation of the position (P2, P4) without providing the first fixing layer (20 c, 124 b) on the part (20 b, 124 e) at the position (P2, P4) different from the position (P1, P3) in the central axis direction corresponding to the joint position (90, 190).

Further, in the first embodiment, as described above, the joint portion (90) is provided on one side in the central axis direction with respect to a central portion (C2) of the slot (12) in the central axis direction, and the first fixing layer (20 c) is provided so as to overlap with a part (20 b) of the first insulating layer (20 a) on the other side in the central axis direction with respect to a position (P1) in the central axis direction corresponding to the joint portion (90). With this configuration, in the part (20 b) of the first insulating layer (20 a) on the other side in the central axis direction with respect to the position (P1) in the central axis direction corresponding to the joint portion (90), the length (L2) in the central axis direction is larger than that of the part (20 f) on the one side. As a result, even if the first fixing layer (20 c) is provided at the position (P2) different from the position (P1) in the central axis direction corresponding to the joint portion (90), it is possible to prevent the length (L2) in the central axis direction of the first fixing layer (20 c) from becoming small. As a result, since a sufficient fixed length (L2) in the central axis direction can be secured, the fixing strength of the leg portion (81) with respect to the armature core (10) by the first fixing layer (20 c) can be prevented from decreasing while decreasing the thermal stress on the joint portion (90).

In the first embodiment, as described above, the first insulating layer (20 a) is provided from one side end portion (10 a) across to the other side end portion (10 b) of the end surface (11 a, 13 a) of the armature core (10) in the central axis direction, and the first fixing layer (20 c) is provided so as to overlap with a part (20 b) of the first insulating layer (20 a) on the other side in the central axis direction with respect to the central portion (C2) in the central axis direction. With this configuration, even if the first fixing layer (20 c) is provided at the position (P2) different from the position (P1) in the central axis direction corresponding to the joint portion (90), it is possible to secure with the first insulating layer (20 a), the insulation performance of the leg portion (81) and the armature core (10) in the entire area in the central axis direction, within the slot (12). As a result, the insulation performance can be improved while the thermal stress on the joint portion (90) is reduced.

Further, in the first embodiment, as described above, the coil portion (30) is formed by joining, in the joint portion (90), among the leg portions (81) of the plurality of segment conductors (40), a short leg portion (71) that is disposed on one side in the central axis direction and that has a first length (L1) in the central axis direction, and a long leg portion (81) that is disposed on the other side in the central axis direction and that has a second length (L2) that is greater than the first length (L1) in the central axis direction, and the first fixing layer (20 c) is provided so as to overlap with a part (20 d) of the first insulating layer (20 a) disposed between the long leg portion (81) and the armature core (10), in the slot (12) or on the outer side of the one slot (12) in the central axis direction. With this configuration, unlike the case in which the first fixing layer (20 c) is provided only between the short leg portion (71) and the armature core (10), since the first fixing layer (20 c) is at least provided between the long leg portion (81), which is relatively long in the central axis direction and the armature core (10), the fixing strength of the coil portion (30) and the armature core (10) can be improved.

Further, in the first embodiment, as described above, the plurality of segment conductors (40) includes a first segment conductor (40) formed in a U-shape by connecting a pair of the short leg portions(71), which are disposed in different slots (12) from each other, to each other, and a second segment conductor (40) that is formed in a U-shape by connecting a pair of the long leg portions (81), which are disposed in different slots (12) from each other, to each other. With this configuration, for each segment conductor (40), two leg portions (71, 81) can be fixed to the armature core (10) with the first fixing layer (20 c). As a result, the fixing strength between the segment conductor (40) and the armature core (10) can be increased as compared to the case in which the segment conductor (40) and the armature core (10) are fixed at one place.

Further, in the first embodiment, as described above, a plurality of the leg portions (71, 81) is provided adjacent to each other in a radial direction of the armature core (10), in the slot (12) or on the outer side of the one slot (12) in the central axis direction, the joint portions (90) of the plurality of leg portions (71, 81) are disposed adjacent to each other in the radial direction, and a first joint portion insulating member (21) that is disposed on one side with respect to the first fixing layer (20 c) in the central axis direction and between the joint portions (90) in the radial direction, and that insulates the joint portions (90) is further provided. With this configuration, since the joint portions (90) can be insulated from each other by the first joint portion insulating member (21), the insulation performance of the armature (100) can be improved. When the joint portion (90) is provided on one side in the central axis direction as in the present embodiment, the first joint portion insulating member (21) can be easily disposed between the joint portions (90) by inserting the first joint portion insulating member (21) in the slot (12) from the one side in the central axis direction with respect to the armature core (10) and disposing the second segment conductor (80) in the slot (12). As a result, the insulation performance between the joint portions (90) can be easily improved.

In the first embodiment, as described above, the first fixing layer (20 c) is provided so as to overlap with a part (20 b) of the first insulating layer (20 a) that does not overlap with the first joint portion insulating member (21) when seen in the radial direction. With this configuration, since it is possible to prevent the total thickness of the core leg portion fixing member (20) and the first joint portion insulating member (21) from increasing, it is possible to decrease the radial width of the part other than the leg portion (71, 81) (the part configured of the first fixing layer (20 c) and the first joint portion insulating member (21)). As a result, even if the first joint portion insulating member (21) is provided in the slot (12), it is possible to prevent the coil space factor in the slot (12) from being decreased.

Further, in the first embodiment, as described above, the first insulating layer (20 a) is disposed at a position (20 f) at which the first insulating layer (20 a) overlaps with the first joint portion insulating member (21) when seen in the radial direction. With this configuration, even in the part (20 f) near the joint portion (90) in which the first joint portion insulating member (21) is disposed and the first fixing layer (20 c) is not provided, the insulating performance between the leg portion (71, 81) and the armature core (10) can be improved with the first insulating layer (20 a) and the insulating performance between the joint portions (90) can be improved with the first joint portion insulating member (21).

In the first embodiment, as described above, each of the plurality of segment conductors (40) is provided with an inclined surface (74, 84), which is inclined with respect to a plane orthogonal to the central axis direction, at a distal end portion of the leg portion (71, 81), and the joint portion (90) is formed by joining the inclined surfaces (74, 84), which face each other in the radial direction, of the plurality of segment conductors (40) that face each other in the central axis direction. Here, in the case where the plurality of segment conductors (40) is pressed along the central axis direction when joining the leg portions (71, 81) to each other, the coil end portion (72, 82) disposed in the outer side of the slot (12) in the central axis direction needs to be pressed. In this case, the coil end portion (72, 82) disposed far away are pressed from within the slot (12) or from the joint portion (90) near the slot (12), and it is not easy to make the pressing force uniform, due to the pressing position and the joining position being spaced away. With respect to this point, according to the above-described embodiment, the pressing force can be applied to the joint portion (90) by pressing the leg portions (71, 81) in the radial direction so as to make the inclined surfaces (74, 84) abut against each other. As a result, unlike the case in which the coil end portions (72, 82) disposed relatively far away are pressed, since the leg portions (71, 81) having the joint portion (90) can pressed so as to press the vicinity of the joint portion (90), it is possible to prevent the pressing force from becoming non-uniform.

In the first and second embodiments, as described above, the first fixing layer (20 c, 124 b) is provided so as to sandwich the first insulating layer (20 a, 124 a) at a part (20 b, 124 e) of the first insulating layer (20 a, 124 a) at a position (P2, P4) different from the position (P1, P3) in the central axis direction corresponding to the joint portion (90, 190). With this configuration, the first insulating layer (20 a, 124 a) and the leg portion (81, 171, 181) can be fixed by the first fixing layer (20 c, 124 b) on one side of the first insulating layer (20 a, 124 a) and the first insulating layer (20 a, 124 a) and the end surface (11 a, 13 a) of the armature core (10) can be fixed by the first fixing layer (20 a, 124 a) on the other side of the first insulating layer (20 a, 124 a). As a result, the leg portion (81, 171, 181) and the armature core (10) can be fixed more firmly, compared to the case in which the first fixing layer (20 c, 124 b) is provided on only one side or the other side of the first insulating layer (20 a, 124 a).

In the first embodiment, the leg portion (71, 81) is covered by an insulating coating (40 a) different from the first insulating layer (20 a). The first insulating layer (20 a) is provided between the leg portion (71, 81) covered by the insulating coating (40 a) and an end surface (11 a, 13 a) of the armature core (10). With this configuration, since the leg portion (71, 81) and the end surface (11 a, 13 a) of the armature core (10) can be insulated by both the insulating coating (40 a) and the first insulating layer (20 a), the insulation between the leg portion (71, 81) and the end surface (11 a, 13 a) of the armature core (10) can be more surely ensured.

In the second embodiment, the plurality of segment conductors (140) includes a plurality of third segment conductors (170) that has a first leg portion (171) that extends to the other side in the central axis direction and that is inserted in the slot (12), among the leg portions (171, 181) that are not covered by an insulating coating and in which a metal surface (140 b) is not exposed, and a plurality of fourth segment conductors (180) that has a second leg portion (181) that extends to one side in the central axis direction, and that is inserted in the slot (12), among the leg portions (171, 181) that are not covered by an insulating coating and in which a metal surface (140 b) is exposed. Further, provided is a second joint portion insulating member (121) that has a sheet shape and that is provided so as to insulate the joint portions (190) from each other, in which the first leg portion (171) having the exposed metal surface (140 b) and the second leg portion (181) having the exposed metal surface (140 b) are in contact without interposing a bonding agent, between coils that are radially adjacent to each other in one slot (12).

With such a configuration, since the coil end portions (172, 182) are insulated from each other by the insulating coating (140 a) and the leg portions (171, 181) (joint portions (190)) are insulated from each other by the second joint portion insulating member (121), the coil end portions (172, 182) and the leg portions (171, 181) can be insulated by different members. In this way, the thickness of each of the insulating coating (140 a) of the coil end portion (172, 182) and the second joint portion insulating member (121) can be individually adjusted. As a result, even when the voltages applied to the coil end portion (172, 182) and the leg portion (171, 181) are different from each other, it is possible to appropriately insulate the coil end portion (172, 182) and the leg portion (171, 181) by adjusting the thickness of each of the insulating coating (140 a) and the second joint portion insulating member (121).

In addition, since the second joint portion insulating member (121) is sheet-shaped, it is possible to easily transmit the pressing force from the inner radial side to the entirety of the joint portions (190) disposed in the radial direction, when the first leg portion (171) and the second leg portion (181) are brought into contact

Further, in the second embodiment, the second joint portion insulating member (121) includes at least two or more facing surface insulating parts (121 a) that cover facing surfaces (190 a) of the joint portions (190) that are radially adjacent to each other, and a circumferential surface insulating part (121 b) that is continuous from both end portions of the facing surface insulating parts (121 a) in a circumferential direction and that covers one circumferential surface (190 b) of the joint portions (190) adjacent in the radial direction for at least a predetermined distance along the radial direction, and the facing surface insulating parts (121 a) adjacent in the radial direction are connected by the circumferential surface insulating part (121 b) in one or another circumferential direction. The second joint portion insulating member (121) includes a joint portion insulating part (121 c) that is formed so that the following are continuous: the facing surface insulating part (121 a) on an outer radial side among a pair of the facing surface insulating parts (121 a) disposed adjacent to each other in the radial direction; the circumferential surface insulating part (121 b) provided on one circumferential side; the facing surface insulating part (121 a) on an inner radial side among the pair of facing surface insulating parts (121 a); and the circumferential surface insulating part (121 b) provided on another circumferential side. The core leg portion fixing member (122) is provided between the slot (12) and the coil portion (130) and is integrally formed with the joint portion insulating part (121 c). With such a configuration, since the joint portion insulating part (121 c) and the core leg portion fixing member (122) can be integrally disposed in the slot (12) in one step, the joint portion insulating part (121 c) and the core leg portion fixing member (122) can be easily disposed in the slot (12).

In the second embodiment, as described above, the core leg portion fixing member (122) has a one side insulating part (122 a) that is continuous with the facing surface insulating part (121 a) on an outermost radial side and that is provided between the slot (12) and the coil portion (130), on one side of the slot (12) in the circumferential direction. The core leg portion fixing member (122) has another side insulating part (122 b) that is continuous with the facing surface insulating part (121 a) on an innermost radial side and that is provided between the slot (12) and the coil portion (130), on another side of the slot (12) in the circumferential direction. With such a configuration, it is possible to prevent conduction of the slot (12) (armature core (10)) and the coil portion (130) in the circumferential direction by each of the one side insulating part (122 a,) and the other side insulating part (122 b). Further, since each of the one side insulating part (122 a) and the other side insulating part (122 b) is continuous with the joint portion insulating part (121 c), the one side insulating part (122 a) and the other side insulating part (122 b) can be disposed in the slot (12) at the same time as the joint portion insulating part (121 c).

Further, in the second embodiment, the one side insulating part (122 a) extends from the end portion (230 a) on the outer radial side to the end portion (230 b) on the inner radial side of the coil portion (130) in the slot (12). The other side insulating part (122 b) extends from the end portion (230 b) on the inner radial side to the end portion (230 a) on the outer radial side of the coil portion (130) in the slot (12). With such a configuration, it is possible to more surely prevent conduction of the slot (12) (armature core (10)) and the coil portion (130) in the circumferential direction by each of the one side insulating part (122 a) and the other side insulating part (122 b).

Further, in the second embodiment, the core leg portion fixing member (122) further has an inner radial side insulating part (122 c) that is continuous with the one side insulating part (122 a) and that is provided so as to cover the facing surface insulating part (121 a) on the innermost radial side from the inner radial side. The core leg portion fixing member (122) has an outer radial side insulating part (122 d) that is continuous with the other side insulating part (122 b) and that is provided so as to cover the facing surface insulating part (121 a) on an outermost radial side from the outer radial side. With such a configuration, it is possible to more surely prevent conduction of the coil portion (130) with the slot (12) (armature core (10)) and the like via the end portions (230 a, 230 b) on both sides of the coil portion (130) in the radial direction, with the inner radial side insulating part (122 c) and the outer radial side insulating part (122 d).

Further, it is possible to prevent the joint portion insulating part (121 c) from expanding in the radial direction and deforming, since the joint portion insulating part (121 c) is sandwiched in the radial direction by the inner radial side insulating part (122 c) and the outer radial side insulating part (122 d). As a result, the work of inserting the joint portion insulating part (121 c) into the slot (12) can be facilitated.

Further, in the second embodiment, a length (L22) of each of the joint insulating portion (121 c) and the core leg portion fixing member (122) in the central axis direction is larger than a length (L62) of the slot (12) in the central axis direction. Each of the joint portion insulating part (121 c) and the core leg portion fixing member (122) is disposed so that edge portions on both sides in the central axis direction protrude outward from an end surface (10 a, 10 b) of the armature core (10) in the central axis direction.

With such a configuration, since each of the joint portion insulating part (121 c) and the core leg portion insulating part (122) is provided in the entire slot (12) in the central axis direction, it is possible to more surely insulate the leg portions (171, 181) from each other (the joint portions (190) from each other) with the joint portion insulating part (121 c), and it is also possible to more surely insulate the leg portions (171, 181) and the slot (12) (armature core (10)) with the core leg portion insulating part (122).

In the second embodiment, as described above, the joint portion insulating part (121 c) includes a second insulating layer (123 a) and a second fixing layer (123 b) that has a second foaming agent (123 c) that foams due to heat and in which the second foaming agent (123 c) foams and expands to fix the coil to the coil adjacent in the radial direction in at least the central axis direction. The second fixing layer (123 b) is provided so as to overlap with a part (123 e) of the second insulating layer (123 a) at a position (P4) different from the position (P3) in the central axis direction corresponding to the joint portion (190). With this structure, it is possible to prevent the second fixing layer (123 b) from entering the joint portion (190) (for example, a clearance portion (171 f, 1810) due to the expansion of the second fixing layer (123 b).

In the second embodiment, as described above, each of a plurality of the joint portions (190) is disposed in a central portion of the armature core (10) in the central axis direction within the slot (12). With such a configuration, it is possible to prevent one of the first leg portion (171) and the second leg portion (181) from becoming excessively heavier than the other. As a result, it is possible to prevent the first leg portion (171) or the second leg portion (181) from becoming too heavy to be fixed by the first fixing layer (124 b).

Further, in the first and second embodiments, as described above, the coil portion (30, 130) is made of a material having a coefficient of thermal expansion (K2) larger than a coefficient of thermal expansion (K1) of the armature core (10). With this configuration, for example, the armature core (10) can be made of a silicon steel plate suitable as a material for the armature core (10), and the coil portion (30, 130) can be formed of a copper material suitable as a material of the coil portion (30, 130). In this case, when the coil portion (30, 130) and the armature core (10) are heated, the expansion length of the coil portion (30, 130) becomes larger than the expansion length of the armature core (10), and when the coil portion (30, 130) and the armature core (10) are cooled, the reduced length of the coil portion (30, 130) becomes larger than the reduced length of the armature core (10). H ere, according to the present embodiment, even if the expansion length and the reduction length of the coil portion (30, 130) and the expansion length and the reduction length of the armature core (10) are different, since the joint portion (90, 190) are not directly fixed to the armature core (10), the relative position of the joint portion (90, 190) with respect to the armature core (10) can change to relieve the thermal stress. As a result, the thermal stress can be effectively relieved while the armature core (10) and the coil portion (30, 130) are made of the optimum material.

Further, in the first and second embodiments, the first fixing layer (20 c, 124 b) is not provided and a clearance (C11, C21) is provided between the joint portion (90, 190) and the end surface (11 a, 13 a) of the armature core (10). The first fixing layer (20 c, 124 b) is provided between a part of the leg portion (81, 171, 181) other than the joint portion (90, 190) and an end surface (11 a, 13 a) of the armature core (10). With this configuration, since the clearance (C11, C21) is provided between the joint portion (90, 190) and the end surface (11 a, 13 a) of the armature core (10), the joint portion (90, 190) can be easily moved relative to the armature core (10). Thus, the thermal stress can be further relieved. As a result, the leg portions (81, 171, 181) other than the joint portions (90, 190) and the end surfaces (11 a, 13 a) of the armature core (10) are fixed by the first fixing layer (20 c, 124 b). At the same time, the thermal stress can be further relieved by the clearances (C11, C21).

[Modifications]

It should be considered that the embodiments presently disclosed are exemplifications in all points and are not restrictive. The scope of the present disclosure is shown by the scope of the claims and not by the above description of the embodiments, and further includes the meanings equivalent to the scope of the claims and all changes (modifications) within the scope.

(First Modification)

For example, in the first and second embodiments, an example is shown in which the first leg portion and the second leg portion of a plurality of segment conductors, which are divided into two in the axial direction and which are disposed to face each other, are joined to form the joint portion in the slot. However, the present disclosure is not limited to this. For example, as in a stator 300 according to a first modification shown in FIG. 33, a first joint portion 391 and a second joint portion 392 may be formed at positions in which the axial positions in the slot 12 are different from each other by joining a first leg portion 371, a second leg portion 372, and a third leg portion 373 of a plurality of segment conductors 340 that are disposed while being divided into three in the axial direction. In this case, a fixing layer 320 c is provided at a position P12 different from a position P11 of the first joint portion 391 in the axial direction and at the position P12 different from a position P13 of the second joint portion 392 in the axial direction. The fixing layer 320 c is an example of a “first fixing layer” in the claims.

(Second Modification)

Further, in the first and second embodiments, examples are shown in which the first conductor and the second conductor are each formed to have a U-shape. However, the present disclosure is not limited to this. For example, as in a stator 400 according to a second modification shown in FIG. 34, a first conductor 470 and a second conductor 480 may each be formed in a J-shape. That is, the first conductor 470 is formed by connecting a short leg portion 471 and a long leg portion 472. The second conductor 480 is formed by connecting a short leg portion 481 and a long leg portion 482.

<Other Modifications>

In the first and second embodiments described above, the examples are shown in which the armature of the present disclosure is configured as the stator. However, the configuration is not limited to this. For example, the armature of the present disclosure may be configured as a rotor having a rotor core and a coil (segment conductor).

In the first embodiment described above, the example is shown in which the first insulating member is formed into a three-layer structure in which an insulating layer is sandwiched between two fixing layers. However, the configuration is not limited to this. For example, the first insulating member may be configured in a two-layer structure by an insulating layer and one fixing layer, or may be configured in a structure of four or more layers by a plurality of insulating layers and a plurality of fixing layers.

In the first and second embodiments described above, the examples are shown in which the foaming agent is included in the fixing layer have been shown. However, the configuration is not limited to this. For example, the fixing layer may be configured of only a thermosetting resin, without including a foaming agent in the fixing layer. An expanding agent having a function of expanding, other than a foaming agent, may be mixed in the fixing layer.

In the first embodiment described above, the example is shown in which the joint portion is provided in the slot. However, the configuration is not limited to this. For example, the joint portion may be provided in a part outside the slot in the axial direction (outside the slot). Specifically, the second leg portion may be disposed so as to pass through the slot in the axial direction, the first leg portion may be joined to the second leg portion, and the joint portion may be formed outside the slot. In this case, a fixing layer is provided between the second leg portion and the circumferential side surface of the teeth and the wall portion of the back yoke.

Further, in the first and second embodiments described above, the examples are shown in which the insulating layer is provided from the end surface on one axial side of the wall portion of the back yoke and the circumferential side surface of the teeth across to the end surface on the other axial side. However, the present disclosure is not limited to this. For example, the insulating layer may be provided only on a part that is a part of either one of the wall portion of the back yoke and the circumferential side surface of the tooth, and is a part from the end surface on one side axial direction to the end surface on the other side. In this case, it is preferable that another insulating member (for example, a second insulating member) is provided in the part in which the insulating layer is not provided.

Further, in the first and second embodiments, the example is shown in which the plurality of joint portions are provided so as to be adjacent to each other in the radial direction within the slot. However, the configuration is not limited to this. For example, only one joint may be provided within one slot or on the outer side of the slot in the axial direction.

In the first embodiment described above, the example is shown in which the second insulating member for insulating the joint portions from each other is provided in the stator. However, the present disclosure is not limited to this. For example, the stator may not be provided with the second insulating member as long as the insulation performance (insulation distance) between the joint portions is sufficiently secured even if the stator is not provided with the second insulating member.

In the first embodiment described above, the example is shown in which the first facing surface that is provided on the first leg portion and that is configured as the inclined surface and the second facing surface that is provided on the second leg portion and that is configured as the inclined surface are joined. However, the present disclosure is not limited to this. For example, the first facing surface and the second facing surface may be configured as flat surfaces along a plane orthogonal to the axial direction, and the flat surfaces may be joined to each other. In this case, the first leg portion and the second leg portion are pressed in a direction facing each other (a direction along the axial direction).

Further, in the first embodiment, the example is shown in which the joint portion is provided only on one end surface side of the center of the stator core in the axial direction. However, the present disclosure is not limited to this. For example, the joint portion may be provided not only on one end surface side of the center of the stator core in the axial direction but also on the other end surface side of the center in the axial direction, or the joint portion may be provided in the center of the stator core in the axial direction.

Further, in the first and second embodiments described above, the examples are shown in which the opening portion is formed on the inner radial side of the stator. However, the present disclosure is not limited to this. For example, the opening portion may be formed on the outer radial side of the stator.

Further, in the first and second embodiments described above, the examples is shown in which the coil is formed as a wave winding coil. However, the present disclosure is not limited to this. For example, the coil may be formed as a distributed winding coil or a centralized winding coil.

In the first and second embodiments described above, the examples are shown in which the cross-sectional shape of the segment conductor is formed to have a flat shape. However, the present disclosure is not limited to this. That is, the cross-sectional shape of the segment conductor may be formed to have a shape other than the flat shape (a circular shape, an elliptical shape, and the like).

Further, in the first and second embodiments described above, the examples are shown in which the slot is configured to be a semi-open type (the opening width is smaller than the width of the slot). However, the present disclosure is not limited to this. For example, the slot may be configured as a full-open type slot having an opening width equal to the width of the slot as long as the characteristics of the stator (armature) are not affected. Due to the characteristics of the stator, a semi-open type is more preferable than a full-open type.

In the first embodiment described above, the examples are shown in which the first leg portion and the second leg portion are joined by the joining material to form the joined portion. However, the present disclosure is not limited to this. For example, a joint may be formed by brazing or welding the first leg portion and the second leg portion.

Further, in the first and second embodiments described above, the examples are shown in which the fixing layer of the present disclosure is formed as the adhesive layer. However, the present disclosure is not limited to this. For example, by using a fixing layer including an expanding material (expanding layer) different from the adhesive layer, the wall portion and the circumferential side surface and the second leg portion may be fixed by being pressed against each other (pressing force), without being adhered.

In the second embodiment described above, the example is shown in which the contact portion insulating part and the core leg portion insulating part are integrally formed. However, the present disclosure is not limited to this. The contact portion insulating part and the core leg portion insulating part may be provided separately (individually).

In the second embodiment described above, the example is shown in which the one side insulating part and the inner radial side insulating part are continuous and the other side insulating part and the outer radial side insulating part are continuous. However, the present disclosure is not limited to this. At least one of the one side insulating part and the inner radial side insulating part and the other side insulating part and the outer radial side insulating part may be provided separately (individually).

In the second embodiment described above, the example is shown in which the fixing layer is provided up to the edge portion of the insulating layer. However, the present disclosure is not limited to this. For example, the fixing layer may be provided only on the part of the insulating layer (other than the part corresponding to the joint portion) housed in the slot

Further, in the first and second embodiments described above, the examples are shown in which the insulating layer and the fixing layer are integrally formed. However, the present disclosure is not limited to this. For example, the insulating layer and the fixing layer may be provided separately, as in the case in which the fixing layer is previously applied to the armature core.

DESCRIPTION OF REFERENCE NUMERALS

10 Stator core (armature core)

10 a, 10 b End surface (end portion of stator core)

11 a Wall portion (end surface of stator core)

12 Slot

13 a Circumferential side surface (end surface of stator core)

20 First insulating member (core leg portion fixing member)

20 a, 124 a Insulating layer (first insulating layer)

20 b, 124 e Part (part at different position)

20 c, 124 b, 320 c Fixing layer (first fixing layer)

20 d, 124 c Foaming agent (first foaming agent)

21 Second insulating member (first joint portion insulating member)

30, 130 Coil portion

40, 140, 340 Segment conductor

40 a Insulating coating

70, 470 First conductor (first segment conductor)

71, 371 First leg portion (short leg portion)

80 Second conductor (second segment conductor)

81, 372 Second leg portion (long leg portion)

90 Joint portion

100, 200, 300, 400 Stator (armature)

121 Insulating member (second joint portion insulating member)

121 a Facing surface insulating part

121 b Circumferential surface insulating part

121 c Contact portion insulating part (joint portion insulating part)

122 Core leg portion insulating part (core leg portion fixing member)

122 a One side insulating part

122 b Other side insulating part

122 c Inner radial side insulating part

122 d Outer radial side insulating part

123 a Insulating layer (second insulating layer)

123 b Fixing layer (second fixing layer)

123 c Foaming layer (second foaming layer)

140 b Conductor surface (metal surface)

170 First conductor (third segment conductor)

180 Second conductor (fourth segment conductor)

171 First leg portion

181 Second leg portion

190 Contact portion (joint portion)

190 a Facing surface

190 b Circumferential surface

230 a End portion (end portion on outer radial side of coil portion)

230 b End portion (end portion on inner radial side of coil portion)

391 First joint portion 

The invention claimed is:
 1. An armature comprising: an armature core provided with a plurality of slots extending in a central axis direction; a coil portion in which leg portions of a plurality of segment conductors disposed so as to face each other in the central axis direction are joined in a joint portion that is in one slot of the slots or that is on an outer side of the one slot in the central axis direction; and a core leg portion fixing member that is provided in the slot, in a part at a position different from the position in the central axis direction corresponding to the joint portion such that the core leg portion fixing member is not provided at the position in the central axis direction corresponding to the joint portion, the core leg portion fixing member including a first fixing layer that fixes the armature core and the leg portion.
 2. The armature according to claim 1, wherein the first fixing layer contains a first foaming agent that foams due to heat, and at a position different from the position in the central axis direction corresponding to the joint portion, the first fixing layer containing the first foaming agent in a foamed state is filled between an end surface of the armature core and the leg portion.
 3. The armature according to claim 1, wherein the core leg portion fixing member further includes a first insulating layer that is provided in the slot, between the end surface of the armature core and the leg portion, and that insulates the end surface of the armature core and the leg portion, and the first fixing layer is provided so as to overlap with a part of the first insulating layer at a position different from the position in the central axis direction corresponding to the joint portion.
 4. The armature according to claim 3, wherein the joint portion is provided on one side in the central axis direction with respect to a central portion of the slot in the central axis direction, and the first fixing layer is provided so as to overlap with a part of the first insulating layer on the other side in the central axis direction with respect to a position in the central axis direction corresponding to the joint portion.
 5. The armature according to claim 4, wherein the first insulating layer is provided from one side end portion across to the other side end portion of the end surface of the armature core in the central axis direction, and the first fixing layer is provided so as to overlap with a part of the first insulating layer on the other side in the central axis direction with respect to the central portion in the central axis direction.
 6. The armature according to claim 4, wherein the coil portion is formed by joining, in the joint portion, among the leg portions of the plurality of segment conductors, a short leg portion that is disposed on one side in the central axis direction and that has a first length in the central axis direction, and a long leg portion that is disposed on the other side in the central axis direction and that has a second length that is greater than the first length in the central axis direction, and the first fixing layer is provided so as to overlap with a part of the first insulating layer disposed between the long leg portion and the armature core.
 7. The armature according to claim 6, wherein the plurality of segment conductors includes a first segment conductor formed in a U-shape by connecting a pair of the short leg portions, which are disposed in different slots from each other, to each other, and a second segment conductor that is formed in a U-shape by connecting a pair of the long leg portions, which are disposed in different slots from each other, to each other.
 8. The armature according to claim 4, wherein a plurality of the leg portions is provided adjacent to each other in a radial direction of the armature core, in the slot or on the outer side of the one slot in the central axis direction, the joint portions of the plurality of leg portions are disposed adjacent to each other in the radial direction, and a first joint portion insulating member that is disposed on one side with respect to the first fixing layer in the central axis direction and between the joint portions in the radial direction, and that insulates the joint portions is further provided.
 9. The armature according to claim 8, wherein the first fixing layer is provided so as to overlap with a part of the first insulating layer that does not overlap with the first joint portion insulating member when seen in the radial direction.
 10. The armature according to claim 8, wherein the first insulating layer is disposed at a position at which the first insulating layer overlaps with the first joint portion insulating member when seen in the radial direction.
 11. The armature according to claim 8, wherein each of the plurality of segment conductors is provided with an inclined surface, which is inclined with respect to a plane orthogonal to the central axis direction, at a distal end portion of the leg portion, and the joint portion is formed by joining the inclined surfaces, which face each other in the radial direction, of the plurality of segment conductors that face each other in the central axis direction.
 12. The armature according to claim 3, wherein the first fixing layer is provided so as to sandwich the first insulating layer at a part of the first insulating layer at a position different from the position in the central axis direction corresponding to the joint portion.
 13. The armature according to claim 3, wherein the leg portion is covered by an insulating coating different from the first insulating layer, and the first insulating layer is provided between the leg portion covered by the insulating coating and an end surface of the armature core.
 14. The armature according to claim 1, wherein the coil portion is made of a material having a coefficient of thermal expansion larger than a coefficient of thermal expansion of the armature core.
 15. The armature according to claim 1, wherein the first fixing layer is not provided and a clearance is provided between the joint portion and the end surface of the armature core, and the first fixing layer is provided between a part of the leg portion other than the joint portion and an end surface of the armature core.
 16. The armature according to claim 1, wherein the joint portion is in one slot of the slots. 